Download Sexual Selection in Males and Females REVIEW

REVIEW
Tim Clutton-Brock
Research on sexual selection shows that the evolution of secondary sexual characters in males and
the distribution of sex differences are more complex than was initially suggested but does not
undermine our understanding of the evolutionary mechanisms involved. However, the operation of
sexual selection in females has still received relatively little attention. Recent studies show that
both intrasexual competition between females and male choice of mating partners are common,
leading to strong sexual selection in females and, in extreme cases, to reversals in the usual
pattern of sex differences in behavior and morphology.
n the Descent of Man (1871), Darwin provided the first coherent explanation of the
elaborate weapons and ornaments found in
males and, less commonly, in females in many
animals. These “secondary” sexual characters
did not appear likely to increase survival, and
he argued that they were a result of intrasexual
competition either for breeding opportunities
or to attract the opposite sex. He termed this
evolutionary process “sexual selection,” describing it as selection that “depends on the advantage which certain individuals have over others
of the same sex and species solely in respect of
reproduction” (1, p. 209).
Our current understanding of Darwin’s theory, based on seminal papers by Bateman (2)
and Trivers (3), is that reduced investment in
gametes and parental care by males increases
their potential rate of reproduction (PRR) (4, 5),
biasing the relative numbers of sexually active
males to receptive females at any one time (the
operational sex ratio, or OSR) (6). Biased OSRs,
in turn, lead to increased intensity of intrasexual
competition, greater variance in breeding success, and stronger selection for traits affecting
competitive ability in males than in females
(3, 6, 7). In addition, they are likely to favor the
evolution of greater selectivity in choice of mating partners by females, generating selection
pressures in males for traits that display their
quality as breeding partners (3, 8). Where secondary sexual characters confer important reproductive benefits, they may develop to a point
where their benefits are offset by substantial costs
to survival, either among juveniles or among
adults (3, 9).
Although the assumptions and predictions
of the theory of sexual selection have withstood
repeated testing (10), recent reviews have pointed
to inconsistencies in relationships between parental investment, reproductive competition, and
sex differences in behavior and morphology,
as well as to the scarcity of detailed studies of
I
Department of Zoology, University of Cambridge, Downing
Street, Cambridge CB2 3EJ, UK. E-mail: [email protected]
1882
Sexual Selection in Males
It is now clear that relationships between relative gamete size, the evolution of parental care,
OSRs, the relative intensity of competition, and
the extent of selectivity in the two sexes are not
the operation of sexual selection in females as straightforward as was originally supposed.
(11–15). Roughgarden et al. (16) recently argued, Sex differences in parental care are not an inevin this journal, that “sexual selection theory is itable consequence of sex differences in gamete
always mistaken, even when gender roles size because patterns of parental care are likesuperficially match the Darwinian templates” ly to coevolve and feedbacks may be complex
and went on to advocate its replacement by a (18, 19). Sex differences in parental investment
are not the only factors affecting the OSR (5, 15):
Biases in the sex ratio at
birth or hatching, sex differences in juvenile or adult
survival or in the proportion of individuals acquiring the resources necessary
to breed, and variation in the
costs of competing may all
affect the relative numbers
of males and females competing for mates in the two
sexes (5, 20–22). Finally,
the OSR is not the only
factor affecting the relative
intensity of intrasexual competition and mate selection
in the two sexes, and the sex
that competes most intensely for breeding partners is
not always less selective in
its choice of mates. For example, the usual tendency
for females to be more selecFig. 1. In many animals, competition between females for breeding tive than males can be reopportunities is intense, and females show pronounced secondary versed where variance in
characters. In polyandrous birds, where males invest heavily in parental female quality is large and
care, females compete intensely more frequently for breeding oppor- males can increase their
tunities than males and are commonly larger than males as in (A) female
fitness by selecting superior
African jacana (Actophilornis africanus). Female competition for breeding
partners (13, 23, 24).
opportunities is also intense in a number of social mammals where
Relationships between infemale rank and breeding success are closely correlated, including (B)
trasexual
competition and
Kalahari meerkats (Suricata suricatta) and (C) spotted hyenas (Crocuta
crocuta). Females have developed pronounced secondary sexual orna- reproductive variance are
ments that attract males in some polygynous or promiscuous species, also more complex than
including (D) savannah baboons (Papio cynocephalus). In a number of early papers suggested. Albirds, both sexes have similar ornaments probably as a result of mutual though variance in fitness
mate-choice, while in a few species, males and females display in is a prerequisite for selecdifferent sites and have developed contrasting coloration. [Credits: (A tion, a substantial proportion
of reproductive variance in
and B) A. Young; (C) M. L. East and H. Hofer; (D) T. Clutton-Brock]
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Sexual Selection
in Males and Females
novel theory of social selection. That 40 evolutionary biologists cooperated to write 10 letters rejecting these criticisms shows that Roughgarden’s
views are unusual (17), but it is clear that the
mechanisms underlying sex differences in reproductive competition and the traits associated with
them are both more diverse and more complex
than was initially realized. In the wake of
Roughgarden et al.’s review, both the exceptions to the basic structure of sexual selection
theory and the operation of sexual selection in
females deserve further attention.
REVIEW
Sexual Selection in Females
Although secondary sexual characters are widespread in females (Fig. 1), Darwin paid little
attention to them, noting in passing that “in
almost every great class a few anomalous cases
occur, where there has been an almost complete
transposition of the characters proper to the two
sexes; the females assuming characters which
properly belong to the males” (1). Subsequent
research on birds showed that a small number of
shore birds have polyandrous mating systems,
which generate female-biased OSRs, more intense
A
B
3
1.0
Offspring surviving to
reproductive maturity per year
RS = – 0.592
Offspring per year
P = 0.001
2
1
0
0
5
10
15
20
RS = – 0.634
P = 0.002
0.8
0.6
0.4
0.2
0
25
0
5
Social rank of mother
10
15
20
25
Social rank of mother
D
100
1000
Females
Cub aggressions
per hour x100
Males
750
500
250
80
60
40
20
0
0
0
10
20
30
0
200
400
600
800
1000
Maternal fecal androgens (ng/g)
Social rank
Fig. 2. Correlates of female rank in spotted hyenas. (A) Total number of offspring produced per year by
the mother shown as a function of the social rank of the mother. (B) Number of offspring surviving to
reproductive maturity produced per year as a function of the social rank of the mother. (C) The relationship
between fecal androgens and social rank in female spotted hyenas during the second half of gestation. (D)
The relationship between maternal androgens measured during the second half of gestation and rates of
aggression in hyena cubs aged 2 to 6 months. [(A) and (B) reproduced from (39) by permission of the
Society for Reproduction and Fertility (2007); (C) and (D) reproduced from (43) by permission]
reproductive competition among females than
males, and greater development of secondary
sexual characters in females (3, 6). However,
with the exception of polyandrous species, relatively little attention has been paid to the operation of sexual selection or the evolution of
secondary sexual characters in females.
Intense reproductive competition among
females is not confined to species where males
invest more heavily than females in their offspring and OSRs are biased toward males and
is widespread in species where males are the
principal competitors. Sexual selection operating in females may reduce the degree of sexual
dimorphism, in some cases leading to monomorphism. For example, in a number of birds
where females and males have similar ornaments, both sexes are commonly involved in
aggressive displays with rivals, indicating that
intrasexual competition may be involved (32, 33).
In a small number of animals, the resources
necessary for successful breeding in females
are so heavily concentrated that reproductive
competition between females is more frequent
or more intense than between males, despite
greater investment in parental care by females
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(34). Examples include several cooperative
breeders where a single female monopolizes
reproduction in each group and her offspring
are reared by other group members (32, 35, 36)
as in Kalahari meerkats (Suricata suricatta),
where females invest more heavily in parental
care than males but depend on access to groups
of nonbreeding subordinates to rear their young
(37). Fewer females than males breed as dominants, and variance in breeding success is
higher in females than in males (34). In naked
mole-rats (Heterocephalus glaber), breeding females suppress reproduction in other females,
evicting or killing challengers, and are larger
and more frequently aggressive than other group
members and dominant to males (38). More intense intrasexual competition among females
than males also occurs in some mammals where
multiple females breed in each group. For
example, in spotted hyenas (Crocuta crocuta),
females compete intensely for social rank,
which is closely related to their breeding success
(Fig. 2) (39).
In many species where females compete
intensely for breeding opportunities, they show
unusual behavioral, physiological, or anatom-
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C
Fecal androgens
(ng/g -1 feces)
both sexes is often caused by age, by random
processes that do not contribute to selection,
or by phenotypic differences that have no heritable basis (7, 13, 14, 25–27), and these effects
may often differ between the sexes. For example, the higher PRR of males may generate increased random variance in breeding success in
males compared to females (25). In addition,
because breeding success is often more strongly
influenced by age in males than in females, calculation of relative variance in breeding success
across individuals of unknown age often overestimates variance in male reproductive success and underestimates variance in female
success (7).
Finally, relationships between relative reproductive variance in the two sexes and the
evolution of sex differences are complex and
inconsistent. Qualitative differences in the selection pressures operating in males and females
are common, leading to the evolution of contrasting secondary sexual characters in males
in different species (7). For example, in some
polygynous shore birds, males fight on the
ground, selection favors large body size, and
males are larger than females, whereas in species where males compete in aerial displays, selection for agility favors small size in males and
males are smaller than females (28). Similarly,
in ungulates, where males fight in pushing contests, there is strong selection for male size and
sexual dimorphism is pronounced, whereas in
species where males fight by biting, body size
does not increase the competitive ability of
males and sex differences in body size are small
(7). In other cases, sex differences in ornamentation are associated with qualitative differences in the selection pressures operating in
males and females rather than with sex differences in reproductive variance. For example, in some birds, males and females compete
at different sites and have developed contrasts
in plumage color related to the sites where
they display (29). Recent examples of sexual
antagonism also provide further evidence of
the importance of qualitative differences in the
selection pressures operating on the two sexes
(27, 30, 31). It is consequently unfortunate that
more attention continues to focus on sex differences in reproductive variance than on differences in the selection pressures operating in
males and females.
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REVIEW
Male bias
Operational sex ratio
B
1.0
0.8
0.6
Female bias
A
larged pinnate leg scales that honestly reflect
their fecundity and males choose females with
large leg scales (51). Fat-padded breasts, thighs,
and buttocks in human females may have evolved
for similar reasons (52). In other cases, female
ornaments appear to reflect temporal changes in
reproductive status. In some primates that live in
groups where females have an opportunity to
mate with more than one male, females show
pronounced swellings of the perineal region
that are largest and brightest around the time
of ovulation and attract the attention of males
(53, 54). The relative size of sexual swellings
differs between females, so these differences
may also signal individual variation in reproductive performance (55). Mutual mate choice
by males and females also occurs in a number
0.4
0.2
0
May
July
Time of season
C
D
Male – male
Female –female
0.5
By males
By females
0.6
0.4
0.5
Courtship
Agonistic behavior
0.7
0.4
0.3
0.3
0.2
0.2
0.1
0.1
0
0
May
July
May
0
0
May
July
Time of season
July
May
July
Time of season
Fig. 3. Seasonal changes in the relative frequency of competition and display in two-spotted
gobies (Gobiusculus flavescens) [reproduced from (66) by permission]. (A) Female and male twospotted gobies. (B) Seasonal changes in the operational sex ratio. (C) Change in male and female
propensity to behave agonistically when encountering same-sex individuals. (D) Change in male
and female propensity to perform courtship.
not only are testosterone levels consistently
higher in dominant females than in subordinates,
but the brain gene expression profiles of dominant females resemble those of males (36).
Male mate choice is also widespread in species where OSRs are male-biased and is often
associated with female courtship of males as
well as with the evolution of conspicuous sexual
ornaments in females. In some cases, female
ornaments reflect individual differences in fecundity and males prefer highly ornamented
partners (21, 49, 50). For example, in some empidid dance flies where males provide nuptial
gifts for females, females have developed en-
1884
of monogamous birds and, like intrasexual competition, may lead to the evolution of similar
ornaments in males and females (24, 49, 56).
Where both sexes invest heavily in their
progeny, the OSR and the relative intensity of
breeding competition in the two sexes sometimes vary throughout the reproductive cycle. In
some fish, intense male:male competition and
frequent male displays at the beginning of the
season are replaced by active competition between females for males and female displays
as the season progresses (Fig. 3). Similarly, in
some polygynous ungulates where males initially compete intensely for females, females that
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have entered estrus and need to mate rapidly
compete for the attentions of defending males
(57, 58). Several studies of species where both
sexes make large investments in their offspring
have shown that the relative intensity of reproductive competition in the two sexes can be
changed by manipulating resource availability
and reversing sex differences in PRR (59, 60).
Contrasts in the Operation of Sexual
Selection in Males and Females
Although intrasexual competition for breeding
opportunities and consistent mating preferences
in the opposite sex appear to have played an
important role in the evolution of secondary sexual characters in both sexes, there are fundamental differences in the operation of sexual
selection in males and females. Because of their
greater energetic investment in gametes and
parental care, females more commonly compete
with each other for access to resources necessary for successful reproduction (including
breeding sites, parental care, and social rank)
than for access to gametes produced by the
opposite sex (33, 34). As a result, the relative
intensity of intrasexual competition and the development of traits that increase competitive
success in females may be more strongly influenced by differences in resource distribution
than by variation in mating systems. Intrasexual
competition between females for resources may
generate large individual differences in fecundity (61) that strengthen selection on males to
identify and prefer superior partners and selection on females to signal temporal and individual
differences in fecundity. Strong selection on females to maximize the growth and survival of
their offspring may also generate selection pressures for mating with genetically compatible partners which, in some cases, may favor mating with
multiple males (62).
There may also be qualitative differences in
the costs of reproductive competition and secondary sexual characters to the two sexes. Although male competition and the evolution of
increased body size in males is commonly associated with higher juvenile mortality and reduced longevity in males compared to females
(9), there is little evidence that sex differences in
survival are reversed in species where reproductive competition is more intense and secondary sexual characters are more highly developed
in females. One possibility is that the costs
of female expenditure on competition or ornamentation depress fecundity or parental investment and that these effects constrain the
development of secondary sexual characters
below the level at which they have measurable
costs to female survival (33). For example, where
increased competitive success in females is associated with elevated testosterone levels, these
may have adverse effects on the fecundity of
females (63) or on the development of their
offspring (64), which constrain the evolution
of further increases.
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ical characteristics. Female meerkats are more
frequently aggressive to each other than are
males, and their body weight has a stronger influence on their chances of acquiring and maintaining dominant status (34). Both in meerkats
and in naked mole-rats, females that attain dominant status show elevated levels of testosterone
at particular stages of the reproductive cycle, as
well as a secondary period of growth (40, 41).
Heightened testosterone levels in breeding females
also occur in spotted hyenas (42, 43) and in some
lemurs (44, 45), as well as in some breeds of
domestic cattle where females have been selected
for competitive ability (46). In a number of these
species, the genitalia of females show evidence
of masculinization (44, 45, 47, 48) while, in the
cooperative cichlid fish (Neolamprolagus pulcher),
Contrasts in the operation of sexual selection
in the two sexes raise the question of whether
adaptations to intrasexual competition in females
should be regarded as products of sexual selection. In the Descent of Man, Darwin commonly describes sexual selection as a process
operating through intrasexual competition to
breed, though where he discusses its operation
in males, he describes it as operating through
competition for mates. Sexual selection is now
commonly defined as a process operating through
intrasexual competition for mates or mating
opportunities, with the result that selection pressures arising from intrasexual competition between females to conceive or rear young are
generally excluded and sexual selection is, by
definition, a process that is largely confined to
males. An unfortunate consequence of this is
that characteristics that increase the competitive
ability of individuals are likely to be attributed
to sexual selection if they occur in males—but
not if they occur in females. As a result, it may
be helpful to return to a broader definition of
sexual selection as a process operating through
intrasexual competition for reproductive opportunities, providing a conceptual framework that
is capable of incorporating the processes leading
to the evolution of secondary sexual characters
in both sexes (65).
Conclusions
Three main conclusions should be drawn from
this review. First, the theory of sexual selection
still provides a robust framework that explains
much of the variation in the development of
secondary sexual characters in males, although
the mechanisms controlling the relative intensity
of reproductive competition and the relative
development of secondary sexual characters in
the two sexes are more complex than was originally supposed. The recognition of these complexities helps to refine the assumptions and
predictions of the theory of sexual selection but
does not undermine its basic structure.
Second, sexual selection operating both through
intrasexual competition for breeding opportunities and through male mating preferences is
common in females and can lead to the evolution of pronounced secondary sexual characters
in females, as well as in males, though there are
important differences in the form and costs of
intrasexual competition between the two sexes.
Consequently, satisfactory explanations of the
evolution of sex differences requires an understanding of the operation of sexual selection in
females as well as in males.
Finally, many important questions about the
operation of sexual selection in females and the
evolution of sex differences have yet to be answered. Where females compete directly with
each other, it is often unclear precisely what
they are competing for. Where females have
developed obvious secondary sexual characters,
it is often uncertain whether these are used principally to attract males or in intrasexual competition for resources, and how their development is
limited is unknown (33, 49). And, where males
show consistent mating preferences for particular categories of females, we do not yet know
whether they are usually selecting for heritable
differences in female quality or for nonheritable
variation in fecundity or for both. There is still
much to be done.
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